Michinori Tanaka

Anti-neovascular therapy using novel peptides homing to angiogenic vessels.

Cancer chemotherapy targeted to angiogenic vessels is expected to cause indirect tumor regression through the damage of the neovasculature without the induction of drug resistance. To develop a tool for neovasculature-specific drug delivery, we isolated novel peptides homing to angiogenic vessels formed by a dorsal air sac method from a phage-displayed peptide library. Three distinct phage clones that markedly accumulated in murine tumor xenografts presented PRPGAPLAGSWPGTS-, DRWRPALPVVLFPLH- or ASSSYPLIHWRPWAR-peptide respectively. After the determination of the epitope sequences of these peptides, we modified liposomes with epitope penta-peptides. Liposome modified with APRPG-peptide showed high accumulation in murine tumor xenografts, and APRPG-modified liposome encapsulating adriamycin effectively suppressed experimental tumor growth. Finally, specific binding of APRPG-modified liposome to human umbilical endothelial cells, and that of PRP-containing peptide to angiogenic vessels in human tumors, i.e., islet cell tumor and glioblastoma, were demonstrated. The present study indicates the usefulness of APRPG-peptide as a tool for anti-neovascular therapy, a novel modality of cancer treatment.

7-Chloro-5-hydroxy-1-[2-methyl-4-(2-methylbenzoyl-amino)benzoyl ]-2,3,4,5-tetrahydro-1H-1-benzazepine (OPC-41061): a potent, orally active nonpeptide arginine vasopressin V2 receptor antagonist.

We previously reported a series of benzazepine derivatives as orally active nonpeptide arginine vasopressin (AVP) V2 receptor antagonists. After the lead structure OPC-31260 was structurally evaluated and optimized, the introduction of the 7-Cl moiety on the benzazepine and 2-CH3 on the aminobenzoyl moiety enhanced its oral activity. The new AVP-V2 selective antagonist OPC-41061 was determined to be a potent and orally active agent.

Suppression of tumor growth by novel peptides homing to tumor-derived new blood vessels.

Novel peptides homing to angiogenic vessels were recently isolated from a phage‐displayed random pentadecapeptide library. One of the isolated peptides, ASSSYPLIHWRPWAR, significantly suppressed the migration of VEGF‐stimulated human umbilical vein endothelial cells. Dendoric ASSSYPLIHWRPWAR‐peptide suppressed the formation of new blood vessels in dorsal air sac model mice. Furthermore, ASSSYPLIHWRPWAR‐peptide and the fragment peptides containing WRP, which is revealed to be an epitope sequence, significantly suppressed the tumor growth, although 15‐mer shuffled peptide derived from ASSSYPLIHWRPWAR and pentapeptides with alanine substitution of each residue of WRP did not. Taken together, ASSSYPLIHWRPWAR‐peptide may cause tumor dormancy through inhibition of angiogenesis, and the WRP sequence may be the minimal and essential sequence for this activity.

Peptide Derivation of Poorly Absorbable Drug Allows Intestinal Absorption Via Peptide Transporter

The purpose of the present study was to examine whether the intestinal absorption of low-permeability drugs could be improved by utilization of the intestinal influx transporter PEPT1. We investigated whether peptide derivatives of poorly absorbable nonamino acid-like drugs might be substrates of PEPT1, using rebamipide (Reb) as a model drug. We synthesized several peptide derivatives of rebamipide and examined their inhibitory effect on the uptake of [(3)H]Gly-Sar by PEPT1-expressing HeLa cells. Some of the peptide derivatives inhibited PEPT1-mediated uptake of [(3)H]Gly-Sar. Next, uptake of the inhibitory peptide derivatives was evaluated in PEPT1-expressing Xenopus oocytes and HeLa cells. Ser(Reb)-Gly exhibited significantly increased uptake by PEPT1-expressing cells in comparison with that by mock cells. The permeability of Ser(Reb)-Gly across a Caco-2 cell monolayer was significantly higher than that of rebamipide itself, and the transport was decreased in the presence of PEPT1 substrates. Further, a rat intestinal perfusion study revealed increased absorption of Ser(Reb)-Gly compared with rebamipide. These results demonstrate that the addition of a dipeptide moiety to a poorly absorbable nonpeptide/nonamino acid-like drug can result in absorption via the intestinal transporter PEPT1, though there is some selectivity as regards the structure of the added peptide moiety.

Suppression of GD1α ganglioside-mediated tumor metastasis by liposomalized WHW-peptide

GD1α ganglioside‐replica peptides were recently isolated from a phage‐displayed random pentadecapeptide library by assaying for inhibition of adhesion of RAW117‐H10 lymphosarcoma cells to hepatic sinusoidal microvessel endothelial (HSE) cells. We show here that the Trp‐His‐Trp (WHW) peptide was identified as a minimal sequence of the GD1α‐replica peptide WHWRHRIPLQLAAGR. The addition of WHW peptide‐attached liposomes displayed efficient inhibition of liver metastasis of RAW117‐H10 cells as well as of GD1α‐mediated adhesion of RAW117‐H10 cells to HSE cells in vitro. These results suggest that engineered liposomes for peptide delivery are applicable to treatment for metastasis.

A new approach for drug discovery from glycobiology and phage-displayed peptide library technology

Peptides which mimic functional activities of glycosphingolipids were prepared by a technology of phage-displayed peptide library using monoclonal antibodies against glycosphingolipids. These peptides were named glyco-replica peptides. Peptides prepared with anti-GD1alpha antibody by this technology were found to contain WHW as common motif, and they showed suppressive activity not only on adhesion between hepatic sinusoidal endothelial cells and lymphosarcoma RAW117-H10 cells, but also on metastasis of the tumor cell to the liver and lung. The WHW motif seems to be important to mimic the functional activity of the ganglioside GD1alpha. Next, we prepared GD3-replica peptides using a monoclonal antibody against GD3 (4F6). A peptide, GD3-P4 with highest affinity to 4F6 was used to immunize mice to examine if the mice show their immune response to raise antibodies against GD3. We confirmed the immune response and succeeded in the production of a monoclonal antibody (3D2) against GD3. The monoclonal antibody 3D2 showed specific binding to GD3 on a thin-layer chromatography plate and also melanoma tissues. Interestingly, the amino acid sequence of the CDR regions of light and heavy chains showed high similarity with those of the original GD3 monoclonal antibody (4F6) used for the preparation of GD3-replica peptide. The technology of the phage-displayed peptide library was applied to in vivo bio-panning study using an angiogenesis experimental model. The obtained peptides were found to show strong binding property to the neo-vasculature system and to be quite useful to carry an anti-tumor drug to the tumor tissue. Based on these experimental results, we discuss about some applications of this method to drug discovery.

GD3-replica peptides selected from a phage peptide library induce a GD3 ganglioside antibody response.

GD3‐replica peptides were obtained from a phage peptide library and an anti‐GD3 monoclonal antibody (Mab) (4F6), and anti‐GD3 Mabs were generated by immunizing a peptide GD3P4. A Mab, 3D2 was found to recognize GD3 by immunohistochemical approaches. Amino acid analysis of heavy and light chain variable regions of 4F6 and 3D2 showed that the respective chains had the same length, and only a few different amino acid substitutions were found. The present data indicate that the immunogenic GD3P4 is processed in a certain size and exposed on the antigen‐presenting cells with a molecular shape quite similar to that of the GD3 epitope in 4F6.

Cilostazol Induces PGI2 Production via Activation of the Downstream Epac-1/Rap1 Signaling Cascade to Increase Intracellular Calcium by PLCε and to Activate p44/42 MAPK in Human Aortic Endothelial Cells

Background Cilostazol, a selective phosphodiesterase 3 (PDE3) inhibitor, is known as an anti-platelet drug and acts directly on platelets. Cilostazol has been shown to exhibit vascular protection in ischemic diseases. Although vascular endothelium-derived prostaglandin I2 (PGI2) plays an important role in vascular protection, it is unknown whether cilostazol directly stimulates PGI2 synthesis in endothelial cells. Here, we elucidate the mechanism of cilostazol-induced PGI2 stimulation in endothelial cells. Methods and Results Human aortic endothelial cells (HAECs) were stimulated with cilostazol and PGI2 accumulation in the culture media was measured. Cilostazol increased PGI2 synthesis via the arachidonic acid pathway. Cilostazol-induced intracellular calcium also promoted PGI2 synthesis via the inositol 1,4,5-trisphosphate receptor. Using RNAi, silencing of PDE3B abolished the induction effect of cilostazol on PGI2 synthesis and intracellular cAMP accumulation. Inhibition of the exchange protein, which was directly activated by cyclic AMP 1 (Epac-1) and its downstream signal the Ras-like small GTPase (Rap-1), abolished cilostazol-induced PGI2 synthesis, but this did not take place via protein kinase A (PKA). Inhibition of downstream signaling, such as mitogen-activated protein kinase (MAPK), phosphoinositide 3-kinase (PI3K) γ, and phospholipase C (PLC) ε, suppressed cilostazol-induced PGI2 synthesis. Conclusions The PDE3/Epac-1/Rap-1 signaling pathway plays an important role in cilostazol-induced PGI2 synthesis. Namely, stimulation of HAECs with cilostazol induces intracellular calcium elevation via the Rap-1/PLCε/IP3 pathway, along with MAPK activation via direct activation by Epac-1/Rap-1 and indirect activation by Epac-1/Rap-1/PI3Kγ, resulting in synergistically induced PGI2 synthesis.